Resistance structure, resistance structure unit, information identification device and biosensor

ABSTRACT

A resistance structure, a resistance structure unit, an information identification device and a biosensor. The resistance structure comprises: a first electrode ( 1 ); a second electrode ( 2 ); a plurality of first resistance elements ( 3 ), wherein one end of each of the first resistance elements ( 3 ) is connected to the first electrode ( 1 ), and the other end thereof is connected to the second electrode ( 2 ); a first fracture ( 11 ), the first fracture ( 11 ) dividing the first electrode ( 1 ) into a first part ( 111 ) and a second part ( 112 ), the first fracture ( 11 ) being located between two adjacent first resistance elements ( 3 ) or disconnecting at least one first resistance element ( 3 ) from the first electrode ( 1 ); and a third electrode ( 4 ), wherein the third electrode ( 4 ) is connected to the first part ( 111 ) of the first electrode ( 1 ).

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.15/318,544, filed Dec. 13, 2016. U.S. application Ser. No. 15/318,544 isa 35 U.S.C. § 371 national phase application of PCT/CN2015/080434, filedMay 30, 2015, which claims priority to Chinese Patent Application No. CN201410287690.3, filed on Jun. 24, 2014. The content of each of theseapplications is incorporated by reference herein in its entirety.

FIELD OF THE INVENTION

The present invention relates to a resistance structure, a resistancestructure unit, an information identification device and a biosensor,and in particular, to a resistance structure, a resistance structureunit, an information identification device, and a biosensor used formedical examination.

DESCRIPTION OF THE RELATED ART

Biosensor technology such as biological test papers has been widely usedin the field of POCT (Point of Care Test, POCT). Taking blood glucosedetection technique as an example, with the advantages of operationconvenience and timely detection, glucometer has been widely used as aninstrument for blood glucose detection. Glucometers are roughly dividedinto two categories: Glucometers based on photochemical detection andthose based on electrochemical detection. In photochemical test papers,blood glucose reacts with enzymes on the photochemical bio-sensing testpaper of glucometer to produce chemical substances that lead to thechange to the labeled substance or change to the absorption/emissionwavelength, and the color change or change to absorption/emissionwavelength is converted into corresponding blood glucose concentrations.In the electrochemical test papers, when blood glucose reacts withenzymes on the electrochemical bio-sensing test paper of glucometer,with the release of electrons, the current change is converted to bloodglucose concentration by the glucometer.

Since each batch of biosensors has minor difference or the samedetection instrument may be used in combination with differentbiosensors to detect different types of analytes (e.g., whole blood,urine, etc.), or the same biosensor may be used in different detectioninstruments, and it is required to set different calibration parametersfor each batch and each type of biosensors.

In terms of blood glucose electrochemical test strips, the inter-batchdifferences such as differences in volume and area between the workingelectrode and reference electrode, amount of enzymes in the reactionzone, and different surface states of reaction electrodes, may exist ineach batch, which will affect the detection results. Prior to delivery,the manufacturer will set a group of special calibration parametervalues for each batch, to confirm that the test results are correct. Inaddition, some biosensor manufacturers may design and produce OEM teststrips using the same biosensor test strips according to customers'needs, which will be used together with different detection instruments.Test strips cannot be cross-used between two kinds of detectioninstruments. Some manufacturers detect different analytes with only onedetection instrument, therefore, before detection, the type of analytesmust be judged to ensure that the test results are correct.

Currently, the calibration chips are used for setting the calibrationparameters on the markets, that is, each batch of biological sensingtest papers is equipped with the corresponding correction chips whichstore the calibration parameters. When in use, users just need to insertthe calibration chips to the detection instrument, and then use thematching batch of test papers to obtain the accurate test results.However, users often forget this step in actual detection, leading toinaccurate test results.

In order to solve this problem, US patent application US20100170791A1discloses an electrode design in which different resistance ratiosbetween a plurality of contacts of the electrode may be assigneddifferent identification information, in other words, differentcorrection parameters may be provided. Users can connect the detectioninstrument to any two contacts of the electrode to obtain differentcalibration parameters, and enter them to the detection instrument forcalibration. However, this invention requires pre-storage of a largenumber of calibration parameters, and a large number of contacts must bedesigned on the biosensor and the detection instruments also needaddition of contacts, leading to increased product cost.

SUMMARY OF THE INVENTION

One object of the present invention is to provide a novel resistancestructure which can be used in an information identification device anda biosensor. Another object of the invention is to provide an ninformation identification device and a biosensor that use the abovenovel resistance structure.

Other objects, features and d advantages of the present invention willbecome apparent from the following detailed description, or may bepartially understood through practices of the invention.

According to some embodiments herein, a resistance structure includes: afirst electrode; a second electrode; a plurality of first resistanceelements, wherein one end of each of the first resistance elements isconnected to the first electrode, and the other end thereof is connectedto the second electrode; a first fracture, the first fracture dividingthe first electrode into a first part and a second part, the firstfracture being located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode; a third electrode, wherein the third electrode is connectedto the first part of the first electrode. a first contact, connectingwith the second part of the first electrode; a second contact,connecting with the second electrode; and a third contact, connectingwith the third electrode.

According to some embodiments herein, the second part of the firstelectrode further has N second fractures, N being a natural numbergreater than 0, each of the N second fractures being located between twoadjacent first resistance elements or disconnecting at least one firstresistance element from the first electrode, the N second fracturesdivide the first part into (N+1) parts, the third electrode is connectedwith one of the (N+1) parts.

According to some embodiments herein, the resistances of the pluralityof first resistance elements are the same each other.

According to some embodiments herein, the resistances of at least partof the plurality of first resistance elements are different.

According to some embodiments herein, the material of the firstelectrode and the second electrode is different from that of the firstresistance element.

According to some embodiments herein, both the resistance of the firstelectrode and the second electrode is less than that of each firstresistance element.

According to some embodiments herein, the second electrode further has Mthird fractures, M being a natural number greater than 0, each of the Mthird fractures being located between two adjacent first resistanceelements or disconnecting at least one first resistance element from thesecond electrode.

According to some embodiments herein, a resistance structure includes: afirst resistance structure; a second resistance structure; a firstcontact, connected to the first resistance structure;

a second contact, connected to the second resistance structure; a thirdcontact, connected to the first resistance structure; a fourth contact,connected to the second resistance structure, wherein the firstresistance structure includes: a first electrode; a second electrode; aplurality of first resistance elements, wherein one end of each of thefirst resistance elements is connected to the first electrode, and theother end thereof is connected to the second electrode; at least onefractures, dividing the first electrode into at least two parts, each ofthe fractures is located between two adjacent first resistance elementsor disconnecting at least one first resistance elements from the firstelectrode, wherein, a first electrical parameter R1 is provided betweenthe first contact and the third contact, and a second electricalparameter R2 is provided between the second contact and the fourthcontact, the first electrical parameter R1 varies with the location ofat least one of the fractures.

According to some embodiments herein, an information identificationdevice, including the resistance structure unit as claimed in any one ofaforesaid claims.

According to the first aspect of the invention, a resistance structureincludes: a first electrode;

a second electrode; a plurality of first resistance elements, whereinone end of each of the first resistance elements is connected to thefirst electrode, and the other end thereof is connected to the secondelectrode; a first fracture, the first fracture dividing the firstelectrode into a first part and a second part, the first fracture beinglocated between two adjacent first resistance elements or disconnectingat least one first resistance element from the first electrode; a thirdelectrode, wherein the third electrode is connected to the first part ofthe first electrode; a first contact, connecting with the second part ofthe first electrode; a second contact, connecting with the secondelectrode; and a third contact, connecting with the third electrode.

According to the first aspect of the invention, on the basis of thefirst aspect, the second part of the first electrode further has Nsecond fractures, N being a natural number greater than 0, each of the Nsecond fractures being located between two adjacent first resistanceelements or disconnecting at least one first resistance element from thefirst electrode, the N second fractures divide the first part into (N+1)parts, the third electrode is connected with one of the (N+1) parts.

According to the seventh aspect of the invention, on the basis of thefirst or second aspect, the second electrode further has M thirdfractures, M being a natural number greater than 0, each of the M thirdfractures being located between two adjacent first resistance elementsor disconnecting at least one first resistance element from the secondelectrode.

According to the sixteenth aspect of the invention, a resistancestructure unit includes the resistance structures as described in anyone of first to fifteenth aspects.

According to the seventeenth aspect of the invention, a resistancestructure includes: a first electrode; a second electrode; a pluralityof first resistance elements, wherein one end of each of the firstresistance elements is connected to the first electrode, and the otherend thereof is connected to the second electrode; N factures, the Nfactures dividing the first electrode into N+1 parts, each of the Nfractures is located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode, N is a natural number greater than 1; a first contact; asecond contact; and a third contact, each of the first contact, thesecond contact and the third contact is connected to or connected via aresistance structure to one of the N+1 parts, the resistance structureincludes at least one resistance elements.

According to the eighteenth aspect of the invention, a resistancestructure includes: a first electrode; a second electrode; a pluralityof first resistance elements, wherein one end of each of the firstresistance elements is connected to the first electrode, and the otherend thereof is connected to the second electrode; N factures, the Nfactures dividing the first electrode into N+1 parts, each of the Nfractures is located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode, N is a natural number greater than 0; a third electrode; afourth electrode; a first sub-resistance structure, including at leastone resistor, where the first sub-resistance structure connects thethird electrode to at least one of the (N+1) parts of the firstelectrode; a second sub-resistance structure, including at least oneresistor, where the second sub-resistance structure connects the fourthelectrode to at least part of the second electrode; a first contact,connecting one of the (N+1) parts of the first electrode;

a second contact, connecting one of the second contact and the fourthelectrode; and a third contact, connecting with the third electrode.

According to the nineteenth aspect of the invention, a resistancestructure includes: a first electrode; a second electrode; a pluralityof first resistance elements, wherein one end of each of the firstresistance elements is connected to the first electrode, and the otherend thereof is connected to the second electrode; N factures, the Nfactures dividing the first electrode into N+1 parts, each of the Nfractures is located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode, N is a natural number greater than 0; a third electrode; afourth electrode; a first sub-resistance structure, including at leastone resistor, where the first sub-resistance structure connects thethird electrode to at least part of the second electrode or one of the(N+1) parts; a second sub-resistance structure, including at least oneresistor, where the second sub-resistance structure connects the fourthelectrode to the third electrode or at least part of the secondelectrode or one of the (N+1) parts;

a first contact, connected to or connected via a third sub-resistancestructure to one of the (N+1) parts of the first electrode, the secondsub-resistance structure at least includes a resistance element; asecond contact; and a third contact, wherein, each of the second contactand the third contact is connected to one of the second electrode, thethird electrode and the fourth electrode.

According to the twentieth aspect of the invention, a resistancestructure includes: a first electrode; a second electrode; a pluralityof first resistance elements, wherein one end of each of the firstresistance elements is connected to the first electrode, and the otherend thereof is connected to the second electrode; N factures, the Nfactures dividing the first electrode into N+1 parts, each of the Nfractures is located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode, N is a natural number greater than 0; a third electrode; afirst sub-resistance structure, including at least one resistor, wherethe first sub-resistance structure connects the third electrode to atleast part of the second electrode; a first contact; a second contact;and a third contact, each of the first contact and the second contact isconnected to or connected via a second sub-resistance structure to oneof the (N+1) parts, the second sub-resistance structure includes atleast one resistance element, the third contact is connected with thethird electrode.

According to the twenty-first aspect of the invention, a resistancestructure includes: a first resistance structure; a second resistancestructure; a first contact, connected to the first resistance structure;a second contact, connected to the second resistance structure; a thirdcontact, connected to the first resistance structure; a fourth contact,connected to the second resistance structure, wherein the firstresistance structure includes: a first electrode; a second electrode; aplurality of first resistance elements, wherein one end of each of thefirst resistance elements is connected to the first electrode, and theother end thereof is connected to the second electrode; at least onefractures, dividing the first electrode into at least two parts, each ofthe fractures is located between two adjacent first resistance elementsor disconnecting at least one first resistance elements from the firstelectrode, wherein, a first electrical parameter R1 is provided betweenthe first contact and the third contact, and a second electricalparameter R2 is provided between the second contact and the fourthcontact, the first electrical parameter R1 varies with the location ofat least one of the fractures.

According the twenty-second aspect of the invention, on the basis of thetwenty-first aspect herein, the second resistance structure includes atleast a portion of the first resistance structure.

According the twenty-third aspect of the invention, on the basis of thetwenty-second aspect herein, one of the second contact and the fourthcontact is a common contact common to one of the first contact and thethird contact.

According the twenty-fourth aspect of the invention, on the basis of thetwenty-third aspect herein, the second electrical parameter R2 varieswith the location of at least one of the fractures.

According the twenty-fifth aspect of the invention, on the basis of thetwenty-first aspect herein, the second resistance structure including: athird electrode; a fifth electrode; a plurality of second resistanceelements, wherein one end of each of the second resistance elements isconnected to the third electrode, and the other end thereof is connectedto the fifth electrode; wherein at least one of the third electrode andthe fifth electrode has at least one second fracture such that the thirdelectrode or the fifth electrode is divided into at least two parts, atleast one of the second fractures is located between two adjacent firstresistance elements or disconnecting at least one first resistanceelements from the third electrode or the fifth electrode.

According to the thirty-second aspect of the invention, on the basis ofthe twenty-sixth aspect herein, the second electrode further has M thirdfractures, M being a natural number greater than 0, each of the M thirdfractures being located between two adjacent first resistance elementsor disconnecting at least one first resistance element from the secondelectrode.

According to the thirty-ninth aspect of the invention, an informationidentification device, including the resistance structure unit asdescribed in any one of the 16^(th), 26^(th)-38^(th) aspects.

According to the fortieth aspect of the invention, on the basis of thethirty-ninth aspect herein, the information identification device isused to identify the identification information through the ratio of anelectrical parameter characterized by the resistance structure to asecond electrical parameter.

According to the forty-second aspect of the invention, on the basis ofthe thirty-ninth aspect herein, the second electrical parameters aredependent or independent of the resistance structure.

According to the forty-third aspect of the invention, on the basis ofthe thirty-ninth aspect herein, the second electrical parameters arefrom a test instrument.

According to the forty-fourth aspect of the invention, a biosensor,including: a biosensor body, including a working electrode and a counterelectrode disposed on an insulating base plate; and an informationidentification device as described in any one of the 39^(th)-43^(rd)aspects, disposed on the insulating base plate.

According to the forty-fifth aspect of the invention, on the basis ofthe forty-fourth aspect, the information identification device and theworking electrode and the counter electrode are located on the samesurface of the insulating base plate, and the information identificationdevice is electrically isolated from the working electrode and thecounter electrode or connected to one of the working electrode and thecounter electrode.

According to the forty-sixth aspect of the invention, on the basis ofthe forty-fourth aspect, the information identification device and theworking electrode and the counter electrode are located on differentsurfaces of the insulating base plate.

According to the forty-seventh aspect of the invention, on the basis ofthe forty-fourth aspect, the first electrode, the second electrode, andthe plurality of first resistance elements are formed by a printingmode.

The resistance structure, resistance structure unit, identificationinformation unit, information identification device and biosensordisclosed herein are simple in structure, rich in formation, which canreduce the cost and lower the processing complexity.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 2 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 3 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 4 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 5 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 6 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 7A and FIG. 7B are schematic diagrams of a resistance structureaccording to an embodiment of the invention.

FIG. 8A to FIG. 8D are schematic diagrams of a resistance structureaccording to an embodiment of the invention.

FIG. 9A to FIG. 9E are schematic diagrams of a resistance structureaccording to an embodiment of the invention.

FIG. 10 is a schematic diagram of a biosensor for detecting analytes.

FIG. 11 is a schematic diagram of a biosensor with informationidentification device according to an embodiment of the invention.

FIG. 12 is a schematic diagram of a biosensor with informationidentification device according to an embodiment of the invention.

FIG. 13 is a schematic diagram of a biosensor with informationidentification device according to an embodiment of the invention.

FIG. 14 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 15 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 16 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 17 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 18 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 19 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 20 is a schematic diagram of a resistance structure according to anembodiment of the invention.

FIG. 21 schematically illustrates a variant of the resistance structureand information identification device according to the presentinvention.

FIG. 22 schematically illustrates a variant of the resistance structureand information identification device according to the presentinvention.

FIG. 23 schematically illustrates a variant of the resistance structureand information identification device according to the presentinvention.

FIG. 24 schematically illustrates an exploded structural view of abiosensor according to some embodiments of the present invention.

DETAILED DESCRIPTION

The invention will be described comprehensively in combination withdrawings and embodiments. However, the embodiments can be implemented ina variety of ways but should not be construed as limited to theembodiments set forth herein; on the contrary, these embodiments areprovided so that the invention will be disclosed comprehensively andcompletely, and the concept of the embodiments will be conveyed to thoseskilled in the art. In the figures, the thickness of region and layer isexaggerated for the purpose of clarity; the same reference numeralsdenote the same or similar parts, so the repeated description thereofcan be omitted.

Furthermore, the features, structures, or characteristics describedherein may be combined in one or more embodiments in any appropriatemode. In the following, numerous specific details are set forth in orderto provide a thorough understanding of embodiments of the presentinvention. However, those skilled in the art should be aware that thetechnical solutions in the invention may be practiced without one ormore of the specific details or other methods, components and materialscan be used, etc. In other circumstances, well-known structures,materials, or operations are not shown or described in detail to avoidobscuring aspects of the invention.

Exemplary embodiments embodying the features and advantages of thepresent invention will be described in detail below. It should beunderstood that various modifications in the various embodiments to theinvention will not be departed from the scope of the invention, anddescriptions and drawings herein are intended to be illustrative ratherthan a limitation of the invention.

The present invention discloses a resistance structure, a unit or deviceincluding the resistance structure and a biosensor, which can generatedifferent codes for the use of detection instrument according todifferent fracture positions corresponding to different electricalparameters. In the following, different embodiment will be described asexamples.

Example 1

FIG. 14 shows the resistance structure shown in the first embodiment ofthe present invention. As shown in FIG. 14, the resistance structureincludes a first electrode 1, a second electrode 2, and a plurality offirst resistance elements 3. A plurality of first resistance elements 3are connected between the first electrode 1 and the second electrode 2.The resistance structure further includes a first contact 21 connectedto first electrode 1 and a second contact 22 connected to secondelectrode 2. The first electrode 1 has a first fracture 11, firstfracture 11 being located between two adjacent first resistance elements3 and dividing first electrode 1 into a first part 111 and a secondpart, but the present invention is not limited thereto; first contact 21is connected to the second part, and a first electrical parameter R1 isprovided between first contact 21 and second contact 22. The firstelectrical parameter R1 may be, for example, a resistance value.However, the present invention is not limited thereto. For example, thefirst electrical parameter R1 can also be impedance, voltage, or currentvalue obtained when the external measurement system is connected tofirst contact 21 and second contact 22. The electrical parametersdiscussed below are similar. It should be noted that, in the presentembodiment and following embodiment, the first part 111 refers to aportion located on the upper side of the drawing, and second part 112refers to a portion located on the lower side of the drawing.

In the present embodiment, as shown in FIG. 14, when the detectiondevice is connected to first contact 21 and second contact 22, the firstelectrical parameter R1 is detected, and the first electrical parameterR1 varies with the position of the first fracture 11. For example, inthe present embodiment, the first electrical parameter R1 is theresistance value, and when the position of the first fracture 11changes, the value of the resistance in the electrical circuit composedof the first electrode 1, a plurality of first resistance element 3 andsecond electrode 2 connected in parallel below the first fracture 11will vary with the number of first resistance elements 3 connected inparallel, therefore, the different location of the first fracture 11will result in difference in first electrical parameter R1.

However, the aforesaid first electrical parameter R1 may be not limitedto a resistance value, but may also be other electrical parameters suchas a current value, a voltage value, etc., which is not limited in theinvention.

Referring to FIG. 14, in this embodiment, first electrode 1 and secondelectrode 2 are electrodes arranged in parallel with each other, and aplurality of first resistance elements 3 are electrodes arranged inparallel between first electrode 1 and second electrode 2, but it is notlimited thereto in the invention. It should be easily understood that,first electrode 1 and second electrode 2 may not parallel to each other.First electrode 1 and second electrode 2 are longitudinal electrodes,and first resistance elements 3 are a plurality of lateral electrodes.The plurality of first resistance elements 3 may be the same as eachother or may be different from each other. In this embodiment, theelectrodes are the same, namely, each of first resistance elements 3 hasthe same material, size, resistivity, etc.

After the detection instrument detects the first electrical parameterR1, the corresponding codes can be calculated according to the formulastored in the detection instrument, or codes can be directly obtainedaccording to the first electrical parameter R1. Different codescorrespond to different information, for example, corresponding todifferent batches of test papers, and test papers for detection ofdifferent types of samples, etc., thus the detection instrument providesdifferent calibration parameters to make the test results more accurate.

Example 2

FIG. 6 is a second embodiment of the resistance structure of the presentinvention. In the present embodiment, the resistance structure has athird electrode 4 and a third contact 23 as compared with the firstembodiment shown in FIG. 14. The third electrode 4 is connected to afirst part 111 of a first electrode 1, and a third contact 23 isconnected to a third electrode 4. The first contact 21, second contact22 and third contact 23 can be connected to the detector.

When the electrodes of the detection instrument are connected to firstcontact 21 and second contact 22, a first electrical parameter R1 isprovided between first electrode 1, a plurality of first resistanceelements 3 connected in parallel located below the first fracture 11 andsecond electrode 2;

When the electrodes of the detection instrument are connected to secondelectrode 22 and third contact 23, a second electrical parameter R2 isprovided between second electrode 2, a plurality of first resistanceelements 3 connected in parallel located above the first fracture 11 andthird electrode 4;

The values of R1 and R2 will vary with the position of fracture 11 onthe first electrode 1, and will therefore change accordingly.

The number of first resistance elements is a natural number, and atleast two, the resistance value can be changed by changing the area,width, material of each or part of first resistance elements, to changeR1, R2 values, for example, as shown in FIG. 8A-8D.

The different material and/or different conductive area of firstresistance element 3 leads to different conductive parameters, wherein,if the first fracture 11 remains the same, the two first resistanceelements 3 are machined to electrodes of two different conductivematerials, or electrodes of the same material but different in area, soas to change the values of R1 and R2, for example, as shown in FIG.9A-9E.

Example 3

FIG. 15 shows the resistance structure as shown in the third embodimentof the present invention. Referring to FIG. 15, in the presentembodiment, second electrode 13 is further provided with third fracture13 as compared with the second embodiment. The third fracture 13 islocated between two adjacent first resistance elements 3 and dividessecond electrode 2 into a first part 121 and a second part 122, and thesecond contact 22 is connected to the first part 121 of the secondelectrode 2.

In the present embodiment, the second electrical parameter R2 varieswith the locations of the first fracture 11 and the third fracture 13,wherein the number of first resistance elements connected to the upperpart 111 of the first fracture 11 is not equal to the number of firstresistance elements connected to the upper part 131 of the thirdfracture 13.

After the detection instrument detects the first electrical parameter R1between the first contact 21 and the second contact 22 and the secondelectrical parameter R2 between the third contact and the secondcontact, the corresponding codes can be calculated according to theformula stored in the detection instrument. Different codes correspondto different information, for example, test papers corresponding todifferent batches, and test papers for detection of different types ofsamples, etc., thus the detection instrument provides differentcalibration parameters to make the test results more accurate.

Example 4

FIG. 16 shows the resistance structure shown in the fourth embodiment ofthe present invention. Referring to FIG. 16, in the present embodiment,the resistance structure further includes the fourth electrode 5 and thefourth contact 24; the fourth electrode 5 is connected with the firstpart 121 of the second electrode 2, and the fourth contact 24 isconnected with the fourth electrode 5. In this embodiment, in additionto the first electrical parameter R1 between first contact 21 and secondcontact 22, and second electrical parameters R 2 between first contact21 and third contact 23, there may be other electrical parametersbetween first contact 21 and fourth contact 24. These electricalparameters can be varied with the location of fractures, so that morecodes can be extended by different combinations of electricalparameters, to correspond to different information.

Example 5

FIGS. 7A and 7B are schematic views of a fifth embodiment of aresistance structure in the invention. In this embodiment, as shown inFIG. 7A, the first electrode 1 has a second fracture 12 in addition to afirst fracture 11, as compared with the resistance structure shown inthe second embodiment in FIG. 6. The first fracture 11 and secondfracture 12 divide the first electrode 1 into a first part 111 locatedabove and a second part 113 located below, and a third part 112 locatedin the middle. In addition, the third part may be connected to the sixthelectrode 7, and one end of which may be connected to the sixth contact26.

Referring to FIG. 7A, a resistance structure may be provided for aninformation identification device or other device. The resistancestructure can be configured, including: a first electrode 1; a secondelectrode 2; a plurality of first resistance elements 3, one end of eachof the first resistance elements 3 is connected to the first electrode1, and the other end thereof is connected to the second electrode 2; Nfractures 11 and 12, the N fractures 11 and 12 dividing the firstelectrode into (N+1) parts 111, 112 and 113, each of N fractures 11 and12 being located between two adjacent first resistance elements 3 ordisconnecting at least one first resistance element 3 from the firstelectrode 1, N being a natural number greater than 1; a first contact21, a sixth contact 26, and a third contact 23.

Each of the first contact 21, the sixth contact 26, and the thirdcontact 23 are connected to one of the (N+1) parts 111, 112 and 113.According to some embodiments, at least one of the first contact 21,second contact 26 or third contact 23 may also be connected to one ofthe (N+1) parts 111, 112 and 113. The resistance structure may includeat least one resistance element. The resistance structure is not shownin FIG. 7A, but reference can be made to FIGS. 21-23.

Example 6

FIGS. 17-18 show the electrical structure as shown in the sixthembodiment. Referring to FIG. 7, compared with the first embodiment, theresistance structure in this embodiment further includes a fifthelectrode 6 and a fifth contact 25, the fifth electrode 6 is connectedeach other and passes through each of the first resistance elements 3.The fifth contact 25 is connected with the fifth electrode 6.

The first electrode 1 has the first fracture 11, which is locatedbetween two adjacent first resistance elements 3 and divides firstelectrode 1 into first part 111 and second part 112. First contact 21 isconnected with second part 112 of first electrode 1. As shown in FIG.18, the second electrode 2 has a second fracture 12, which is locatedbetween two adjacent first resistance elements 3. There is at least onefractures in first fracture 11 and second fracture 12.

Electrical parameter R1 can be provided between first contact 21 andfifth contact 25, and electrical parameter R3 can be provided betweensecond contact 22 and fifth contact 25.

S=K*R1/R3, where, the electrical parameters of R1 or R3 may vary withthe fracture position, and more codes can be extended by differentcombinations of electrical parameters to correspond to differentinformation.

Example 7

FIGS. 19-20 are the electrical structures shown in the seventhembodiment of the present invention. As shown in FIG. 19, the resistancestructure in this embodiment further includes third electrode 4 andthird contact 23 as compared with the sixth embodiment. Third electrode4 is connected with first part 111 of first electrode 1, and thirdcontact 23 is connected with third electrode 4. Of which, electricalparameter R1 is provided between first contact 21 and fifth contact 25,electrical parameter R2 is provided between third contact 23 and fifthcontact 25, and electrical parameter R3 can be provided between secondcontact 22 and fifth contact 25. In the present embodiment, theseelectrical parameters vary with the fracture position, and more codescan be extended by different combinations of electrical parameters tocorrespond to different information.

Example 8

FIGS. 1 to 3 show the eighth embodiment of the present invention,showing a schematic view of the resistance structure. Referring to FIG.1, the resistance structure in this embodiment further includes thefourth electrode 5 and the fourth contact 24 as compared with theseventh embodiment. The fourth electrode 5 is connected to first part121 of second electrode 2, and fourth contact 24 is connected to fourthelectrode 5. Electrical parameter R4 is provided between fourth contact24 and fifth contact 25. The first electrical parameter R1, secondelectrical parameter R2, third electrical parameter R3 and fourthelectrical parameter R4 vary with the positions of first fracture 11 andsecond fracture 12, so that more codes can be extended by combinationsof different electrical parameters to correspond to differentinformation.

In this embodiment, a plurality of first resistance elements 3 arearranged in parallel and the same as each other, and the fifth electrode6 passes through the middle point of the first resistance element 3 inthe length direction, namely, each first resistance element 3 can bedivided into two parts of equal length. In practices, the two parts maybe of unequal length.

The first electrode 1, the second electrode 2, the third electrode 4,the fourth electrode 5 and the fifth electrode 6 are connected to thedetection instrument through the first contact 21, the second contact22, the third contact 23, the fourth contact 24, and the fifth contact25. The electrodes of the detection instrument are connected todifferent contacts, to obtain corresponding correction informationparameters, which is described in detail below.

R1-R4 may vary with the positions of first fracture 11 and secondfracture 12, and more codes can be extended by different combinations ofelectrical parameters to correspond to different information.

When the position of fracture is unchanged, the fifth electrode is notin the midpoint of the first resistance element, which causes differentresistance of the left and right parts of the first resistance element.The electrical parameter Rn may also be changed, thereby changing the Snvalue.

Example of Information Identification Device

The present invention provides an information identification device,including an insulating base plate and a resistance structure disposedon an insulating base plate. Of which, the resistance structure may bethe one as mentioned in above embodiment. It will be described incombination with embodiments below.

The First Embodiment of the Information Identification Device

In the first embodiment of the information identification device, takingthe embodiment of FIG. 1 is taken as an example, as shown from FIG. 1,first electrical parameter R1 is provided between third contact 23 andfifth contact 25, electrical parameter R2 is provided between firstcontact 21 and fifth contact 25, and electrical parameter R3 can beprovided between second contact 22 and fifth contact 25, and electricalparameter R4 is provided between fourth contact 24 and fifth contact 25,when the information identification device of the eighth embodiment ofthe present invention is connected with the detection instrument viaelectrodes and contacts, the detection instrument measures theresistance values of the electrode circuit as Rn and R′n, and theresistance ratio Sn is obtained by the equation as follows:

${Sn} = {{Kn}*\frac{Ra}{Rb}}$

Where n=1-4, Sn is the resistance ratio, Kn is the correctioncoefficient, and the correction coefficient is obtained by many tests tomake the actual value approximate to theoretical value in the actualprocess. Ra and Rb represent any two values of R1-R4, a=1-4, b=1-4, a b,with a total of 12 combinations, as follows:

${S\; 1} = {K\; 1*\frac{R\; 1}{R\; 2}}$${S\; 2} = {K\; 2*\frac{R\; 3}{R\; 4}}$${S\; 3} = {K\; 3*\frac{R\; 1}{R\; 3}}$${S\; 4} = {K\; 4*\frac{R\; 1}{R\; 4}}$${S\; 5} = {K\; 5*\frac{R\; 2}{R\; 1}}$${S\; 6} = {K\; 6*\frac{R\; 2}{R\; 3}}$${S\; 7} = {K\; 7*\frac{R\; 2}{R\; 4}}$${S\; 8} = {K\; 8*\frac{R\; 3}{R\; 1}}$${S\; 9} = {K\; 9*\frac{R\; 3}{R\; 2}}$${S\; 10} = {K\; 10*\frac{R\; 4}{R\; 1}}$${S\; 11} = {K\; 11*\frac{R\; 4}{R\; 2}}$${S\; 12} = {K\; 12*\frac{R\; 4}{R\; 3}}$

Where, K1, K2, . . . , K12 are the correction coefficients,respectively.

In actual applications, a S value or a combination of multiple S valuescan be selected for identification of information as required, forexample, the detection instrument can select corresponding technicalparameters according to different S1 value, or select correspondingtechnical parameters according to the combination of S1 and S2 values.In general, when calculated according to the above formula, two groupsof S1, S2 that are not associated in the circuit are selected as thebest and simplest way.

According to different biosensor production batches, differentcalibration parameter calibration equations, and instrument models ordifferent analytes to be determined, the electrodes of detectioninstrument can be connected to different contacts, thereby theinformation identification device gives different resistance ratio S1 toS12. The detection instrument selects appropriate technical parametersbased on different information of S1-S12 and the combinations thereof,finally the detection results are obtained or which type of analytedetection is carried out.

In addition, the present invention is not limited to above examples. Forexample, an electrical parameter is provided between any two contactsfrom first contact 21 to fifth contact 25, and any two encodedparameters applicable to the above formula can be selected for encoding.

Referring to FIG. 2, when the positions of the first fracture 11 and/orthe second fracture 12 are changed, the Ra and Rb are changed so thatthe respective Sns are changed, and thereby the recognition informationgiven by Sn is also changed accordingly.

Referring to FIG. 1 and FIG. 2, in this eighth embodiment, theresistance value of each first resistance element 3 is substantially thesame, e.g. R′, and the resistances of the first electrode 1, the secondelectrode 2, the third electrode 4, the fourth electrode 5 and the fifthelectrode 6 can be ignored, then

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{\frac{1}{( \frac{1}{\frac{R^{`\prime}}{2}} )*x_{1}}}{\frac{1}{( \frac{1}{\frac{R^{`\prime}}{2}} )*x_{2}}}} = {K\; 1*\frac{x_{2}}{x_{1}}}}}$

Where, x1 is the number of circuits between the third contact 23 and thefifth contact 25 that pass through the first resistance element 3; x2 isthe number of circuits between the first contact 21 and the fifthcontact 25 that pass through the first resistance element 3. Similarly,

${S\; 2} = {{K\; 2*\frac{R\; 3}{R\; 4}} = {{K\; 2*\frac{\frac{1}{( \frac{1}{\frac{R^{`\prime}}{2}} )*x_{3}}}{\frac{1}{( \frac{1}{\frac{R^{`\prime}}{2}} )*x_{4}}}} = {K\; 2*\frac{x_{4}}{x_{3}}}}}$

Where, x3 is the number of circuits between the second contact 22 thefifth contact 25 that pass through the first resistance element 3; x4 isthe number of circuits between the fourth contact 24 and the fifthcontact 25 that pass through the first resistance element 3.

Therefore, when the resistance of each first resistance element 3 issubstantially the same, the ratio of the resistance values betweendifferent circuits is equal to the reciprocal of the number of the firstresistance elements 3 connected in parallel in the circuit. Of course,the invention is not limited thereto. When the ratio cannot be obtainedby the number of resistance elements, the ratio can be available fromthe resistance values by calculation or simulation.

S value can be set to a value within a range of error, for example, whenthe range of error is

${{\text{?} \pm \frac{1}{2x^{\prime}}},{\text{?}\text{indicates text missing or illegible when filed}}}\mspace{346mu}$

the same group of technical parameters are used for detection andcalculation of results within the range of

$S \pm {\frac{1}{2x}\text{?}}$?indicates text missing or illegible when filed                    

The Second Embodiment of the Information Identification Device

As shown in FIG. 3, when first resistance element 3 is divided into twosections with unequal length by the fifth electrode 6, the S value inthe eighth embodiment also changes, so as to achieve the purpose ofinformation identification.

For example, when the first resistance element 3 is divided by the fifthelectrode 6 into two sections with length ratio of 3:1 and theresistance of 1 unit is n, then the actual resistance is 3n:n and the S3can be calculated according to the following way:

${S\; 3} = {{K\; 3*\frac{R\; 1}{R\; 3}} = {{K\; 3*\frac{\frac{1}{( \frac{1}{3n} )*x_{1}}}{\frac{1}{( \frac{1}{n} )*x_{3}}}} = {K\; 3*\frac{3x_{3}}{X_{1}}}}}$

The Third Embodiment of the Information Identification Device

Referring to FIG. 6, when the information identification device iselectrically connected with the detection instrument via electrodes andcontacts, the detection instrument calculates S1 according to R1 and R2,and selects appropriate technical parameters based on information ofdifferent S1 values, finally the detection results are obtained or whichtype of analyte detection is carried out. Of which, S1 can be calculatedaccording to the following formula:

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{\frac{1}{R^{\prime}*x_{1}}}{\frac{1}{R^{\prime}*x_{2}}}} = {K\; 1*\frac{x_{2}}{x_{1}}}}}$

The Fourth Embodiment of the Information Identification Device

Referring to FIG. 7A and FIG. 7B, with the increase in fracture, R1 andR2 will vary with the position of the first fracture 11, second fracture12 on the electrode, thus, S1=K1*R1/R2 will also change accordingly.When the contact of the resistance structure described in FIG. 7 iselectrically connected with the detection instrument, the detectioninstrument selects appropriate technical parameters based on informationof different S1 values, finally the detection results are obtained orwhich type of analyte detection is carried out. Alternatively, theresistance structure in the present embodiment may be further simplifiedas shown in FIG. 7B, that is, a plurality of first resistance element 3,the sixth electrode 7, and the sixth contact 26 that are connected tothe third part of first electrode 1 are omitted compared with FIG. 7A.Users can connect the detection instrument with first contact 21 andsecond contact 22 or with second contact 22 and third contact 23 todetect R1 and R2. The detection instrument calculates S1 according to R1and R2, and selects appropriate technical parameters based oninformation of different S1 values, finally the detection results areobtained or which type of analyte detection is carried out. Of which, S1can be calculated according to the following formula:

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{\frac{1}{R^{`\prime}*X_{1}}}{\frac{1}{R^{`\prime}*X_{2}}}} = {K\; 1*\frac{x_{2}}{x_{1}}}}}$

The Fifth Embodiment of the Information Identification Device

Referring to FIGS. 8A to 8D, R1 and R2 will vary with the position ofthe first fracture 11, second fracture 12 on the electrode, thus, S1will also change accordingly. When the information identification devicein FIGS. 8A to 8D and the detection instrument are electricallyconnected via contacts, the detection instrument selects appropriatetechnical parameters based on information of different S1 values,finally the detection results are obtained or which kind of instrumentmodel is used or which type of analyte detection is carried out.

Assuming that the ratio of the area of the upper to the lower blocks is1:2, then

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{2}{1}} = {2K\; 1}}}$

The Sixth Embodiment of the Information Identification Device

Referring to FIG. 9A to 9E, taking FIG. 9A as an example, if the ratioof area of the first resistance element 3 at the upper part to the firstresistance element 3 at the lower part is 1:2, and the ratio ofconductivity is 1:3, then R1:R2=6:1,

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{6}{1}} = {6K\; 1}}}$

For another example, taking FIG. 9D as an example, if the ratio ofmaterial conductivity of the upper and the lower two first resistanceelements 3 is 1:3, the resistance of single first resistance element 3at the lower part is n, and the area of the lowest electrode block is 20times of the area of the first resistance element, then

${S\; 1} = {{K\; 1*\frac{R\; 1}{R\; 2}} = {{K\; 1*\frac{\frac{1}{( \frac{1}{3n} )*x_{1}}}{\frac{1}{{( \frac{1}{n} )*x_{2}} + ( \frac{1}{\frac{n}{20}} )}}} = {K\; 1*\frac{3( {20 + x_{2}} )}{x_{1}}}}}$

According to different biosensor production batches, differentcalibration parameter calibration equations, and instrument models ordifferent analytes to be determined, the electrodes of detectioninstrument can be connected to different contacts, thereby theinformation identification device gives different resistance ratio Sn.The detection instrument selects appropriate technical parameters basedon different information of Sn and the combinations thereof, finally thedetection results are obtained or which type of analyte detection iscarried out.

FIGS. 21-23 show variant forms of resistance structure and informationidentification device according to the present invention.

As shown in FIG. 23, the information identification device can beobtained by modification and/or combination of the structure shown inFIG. 6.

The structure shown in FIG. 23 may include a plurality of units, such asunit 1011 and unit 1012. Each unit may include an informationidentification device as shown in FIG. 6 or a portion thereof. Forexample, the unit 1011 is the structure shown in FIG. 6; and the unit1012 is a portion of the structure shown in FIG. 6, i.e., the thirdelectrode 4 and contact 23 are removed from the structure shown in FIG.6. The plurality of units may be electrically connected or electricallyisolated, as shown in FIG. 23.

A plurality of units can correspond to a code or part of code accordingto the formula Sn=Kn*Ra/Rb, where Ra and Rb are different electricalparameters determined by the same unit among multiple units or differentelectrical parameters determined by the combination of different units,or Ra can be a different electrical parameter determined by one or moreunits among multiple units while Rb can be another independentelectrical parameter. Kn is the coefficient, Sn varies with the positionof first fracture, as shown in FIG. 6. The electrical parameters andanother independent electrical parameter may include resistance, voltageand current.

Referring to FIGS. 21-22, the first sub-resistance structure 411,including at least one resistor 3 a, where the first sub-resistancestructure connects the third electrode 4 to at least one of the (N+1)parts of the first electrode 1. The second sub-resistance structure,including at least one resistance element 711 or resistance element 711and resistance element 511 (resistance structure 511 includes at leastone resistance element 3 c), to connect fourth electrode 5 to at leastpart of second electrode 2.

Referring to FIGS. 21-22, the third resistance structure 61 includes atleast one resistor 3 b, to connect the fifth electrode 6 to at leastpart of second electrode 2 or one of (N+1) parts 111, 112 and 113.

The first sub-resistance structure 411, the second sub-resistancestructure 560, and the third sub-resistance structure 611 can be used toexpand the structures of resistance structures and informationidentification devices, and determine various electrical parameters andelectrical parameter ratios through combination of different contacts,as shown in FIGS. 21-23, but not limited thereto.

Referring to FIG. 23, another variant of the resistance structure mayinclude a first resistance structure 1011, a second resistance structure1012, a first contact 21 connected to the first resistance structure, afifth contact 25 connected to the second resistance structure, a thirdcontact 23 connected to the first resistance structure, a sixth contact26 connected to the second resistance structure. The first resistancestructure 1011 and the second resistance structure 1012 may beindependent resistance structures or may be associated resistancestructures.

The first resistance structure 1011 may include: a first electrode 1; asecond electrode 2; a plurality of first resistance elements 3, whereinone end of each of the first resistance elements 3 is connected to thefirst electrode 1, and the other end thereof is connected to the secondelectrode 2; at least one fractures 11 and 12, dividing the firstelectrode 1 into at least two parts 111, 112 and 113, at least one offractures 11 and 12 being located two adjacent first resistance elements3 or disconnecting at least one first resistance element 3 from thefirst electrode 1.

A first electrical parameter R1 is provided between the first contact 21and the third contact 23, and a second electrical parameter R2 isprovided between the fifth contact 25 and the sixth contact 26. Theresistance structure is configured such that the first electricalparameter R1 varies with the position of at least one of the fractures11 and 12.

According to some embodiments, the second resistance structure mayinclude at least a portion of the first resistance structure, as shownin FIGS. 21-23.

According to some embodiments, one of the fifth contact 25 and the sixthcontact is 26 a common contact common to one of the first contact 21 andthe third contact 23, that is, as shown in FIGS. 21-22, the firstresistance structure is connected with the second resistance structure,and the first contact 21 can be used as a contact to match with thethird contact 23 and the sixth contact 26. In this case, the fifthcontact 25 may be omitted.

According to some embodiments, the resistance structure may beconfigured such that the second electrical parameter R2 varies with theposition of at least one of the fractures 11 and 12.

According to some embodiments, the second resistance structure mayinclude: a second electrode 2; a fifth electrode 6; a plurality ofsecond resistance elements 3 b each having one end connected to secondelectrode 2 and the other end connected to fifth electrode 6; At leastone of the second electrode 2 and the fifth electrode 6 has at least onesecond fracture 13 such that the second electrode 2 or/and the fifthelectrode 6 is divided into at least two parts, and at least one secondfracture 11 and 12 are each located between two adjacent firstresistance elements 3 or dividing at least one first resistance elements3 from the second electrode 2 or the fifth electrode 6.

The second resistance structure may be configured similarly to the firstresistance structure. The configuration of the first resistancestructure and the second resistance structure is not limited to theillustrated example, which may be any structure disclosed in theinvention. The configuration of the second resistance structure mayinclude any resistance element, including but not limited to that shownin FIGS. 21-23.

The information identification device may include the above resistancestructure. The first electrical parameter R1 and the second electricalparameters R2 may correspond to a code or a portion of a code accordingto the formula Sn=Kn*Ra/Rb, where Sn is code or a portion of a code, Rais one of R1 and R2, Rb is one of R1 and R2, and Kn is a coefficient.According to some embodiments, Kn is associated with a manufacturingprocess.

In any one of the foregoing structures, the resistance of the pluralityof first resistance elements 3 may be the same as each other.

In any one of the foregoing structures, the resistance of at least partof the plurality of first resistance elements 3 may be different fromeach other.

In any one of the foregoing structures, the materials of the firstelectrode 1 and the second electrode 2 may be different from those ofthe first resistance element 3.

In any one of the foregoing structures, both the resistance of the firstelectrode 1 and that of the second electrode 2 may be less than theresistance of each first resistance element 3.

In any one of the foregoing structures, a first electrode 1 and a secondelectrode 2 may include silver, and a plurality of first resistanceelements 3 may include graphite.

In any one of the foregoing structures, the second electrode 2 furtherhas M third fractures 13, M being a natural number greater than 0, eachof the M third fractures 13 being located between two adjacent firstresistance elements 3 or disconnecting at least one first resistanceelement 3 from the second electrode 2.

In any one of the foregoing structures, the materials of the pluralityof first resistance elements 3 are the same each other. The material andsize may be the same each other.

In any one of the foregoing structures, the plurality of firstresistance elements 3 include a plurality of resistor stripes disposedin parallel to each other.

In any one of the foregoing structures, the plurality of firstresistance elements 3 include at least two resistor discs.

In any one of the foregoing structures, the material of part of theplurality of first resistance elements 3 may be different from that ofother first resistance elements 3.

In any one of the foregoing structures, the size of part of theplurality of first resistance elements 3 is different from that of otherfirst resistance elements 3.

In any one of the foregoing structures, a fracture is formed by lasercutting or mechanical perforating way.

Example of Biosensor

FIG. 10 is a schematic diagram of a biosensor body for detectinganalytes. The biosensor body 9 may incorporate the aforesaid informationidentification device 1 to constitute a biosensor. As shown in FIG. 10,the biosensor body 9 includes a working electrode 92 and a counterelectrode 93, and an insulating substrate 93 for disposing two testelectrodes. At least one of the working electrode 92 and the counterelectrode 93 is provided with a reaction reagent layer.

FIG. 11 shows a schematic diagram of a first biosensor with aninformation identification device according to an embodiment of thepresent invention. As shown in FIG. 11, the information identificationdevice 1 is disposed on the back surface of the biosensor body 9 and iselectrically isolated from the working electrode 92 and a counterelectrode 93 through the insulating substrate 93, of which, theuppermost three-layer structures are reaction layer, channel layer andupper cover layer respectively.

FIG. 12 shows a schematic diagram of a second biosensor with aninformation identification device according to an embodiment of thepresent invention, wherein the information identification device 1 islocated on the front side of the biosensor body 9 and is isolated fromthe working electrode 92 and the counter electrode 93.

FIG. 13 shows a schematic diagram of a third biosensor with aninformation identification device according to an embodiment of thepresent invention, wherein the information identification device 1 islocated on the front side of the biosensor body 9 and is adjacent to theworking electrode 92 and the counter electrode 93. Informationidentification device 1 is connected with the counter electrode 93 ofbiosensor to save space, while electrical isolation may simplify theinstrument design, thus, those skilled in the art may select them asrequired.

FIG. 24 schematically illustrates a structural exploded view of abiosensor according to some example embodiments of the presentinvention.

Referring to FIG. 24, a biosensor 2400 according to some embodiments ofthe present invention includes an insulating substrate 91, a functionalelectrode and an information identification device 2409, an insulatinglayer 2407, a reaction reagent layer 2405, a channel layer 2403, and atop cover layer 2401.

The insulating substrate 91 may, for example, be an insulating sheet,which is electrically insulative. The materials for the insulatingsubstrate 91 may include, but not limited to, polyethyleneterephthalate, polyethylene, polystyrene, polyester, polypropylene,polycarbonate, polyvinyl chloride, resin, ceramics, and other insulatingmaterials.

The function electrode and information identification device 2409 mayinclude a working electrode 92 and a counter electrode 93 and aninformation identification device as described above. The workingelectrode 92 and counter electrode 93 are used as functional electrodes.The functional electrodes are not limited to the working electrode andthe counter electrode, and other electrodes may be added according tothe practical applications.

The information identification device and the functional electrodes maybe located on the same surface of the insulating base plate 91. In thiscase, the information identification device may be electrically isolatedfrom the working electrode 92 and the counter electrode 93 or may beconnected to one of the working electrode 92 and the counter electrode93. Besides, FIG. 24 shows that the information identification deviceand the functional electrode are located on the same surface of theinsulating base plate 91, but the present invention is not limitedthereto, for example, the information identification device andfunctional electrodes may be located on different surfaces of theinsulating base plate 91.

The materials used for the functional electrode may be any appropriateconductive material, including but not limited to, carbon, silver orsilver chloride, gold, platinum and a mixture with other appropriateconductive material or conductive substance or combinations thereof. Forexample, the electrode at the end in contact with reaction reagent mayuse graphite, and the part of the electrode at the rear end in contactwith detection instrument may use a silver material.

The information identification device may be any of the informationidentification devices or variants thereof as described above. Theinformation identification device may include any of the resistancestructures or variants thereof as described above. The resistanceelement of information identification device may be a resistor stripe,or a standard resistor disc.

The insulating layer 2407 includes an opening to expose a portion of theworking electrode and the counter electrode. The material of theinsulating layer may include, without limitation to, thermal drying typeinsulating ink or ultraviolet curing type insulating ink, insulatingtape, and etc.

The reaction reagent layer 2405 is disposed in the opening of thehydrophobic insulating layer, which contains reagents for identifyingbiological samples and varies with the test samples. For example, thereaction reagents of an electrochemical biosensor include anoxidoreductase and an electron mediator that react with a sample togenerate an electrical signal.

The channel layer 2403 is a channel for sample injection, whichfunctions together with the pore of the top cover layer. Samples enterthe channel via the capillary force. During sample injection, the air atthe front end of channel is discharged via the pore to achieve smoothsample injection. The material of channel layer includes but not limitedto double-sided adhesive tape.

The top cover layer 2401 includes a pore, which is located at the top ofthe channel of the channel layer away from the inlet end. The lowersurface of the top cover layer may be coated with a hydrophilicmaterial. The pore and hydrophilic material may enhance the capillaryaction of the channels. The material of the top cover layer istransparent or translucent, to facilitate observation of sampleinjection or not in the reaction zone.

Depending on the identification information carried by theidentification information system, the detection system may select thecorresponding technical parameters, to finally obtain the test resultsor judge which type of analyte is to be tested.

The electrical parameters described herein include but not limited toresistance, current, voltage, etc.

Compared with the prior art, the structures and constructions of theinformation identification device and biosensor disclosed herein canreduce the cost, simplify the processing complexity, and facilitateinformation expansion.

It should be noted that, the methods for generating correctionparameters of the biosensor and the information identification devicedescribed herein are not limited to graphical examples listed above,which should include various solutions devised within the concept of theinvention.

For example, a resistance structure according to the present disclosuremay be used in combination, the resistance structure may include a firstelectrode; a second electrode; a plurality of first resistance elements,wherein one end of each of the first resistance elements is connected tothe first electrode, and the other end thereof is connected to thesecond electrode; a first fracture, the first fracture dividing thefirst electrode into a first part and a second part, the first fracturebeing located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the firstelectrode. It will be readily understood that various informationidentification devices can be obtained by combining the resistancestructures according to the present invention without departing from thespirit and instructions of the present invention. The plurality ofinformation identification devices may have different coding schemes.The above resistance structure can also be applied to othercircumstances in addition to embodiments of the present invention.

The aforesaid resistance structure may further include a thirdelectrode, wherein the third electrode is connected to the first part ofthe first electrode; a first contact, connecting with the second part ofthe first electrode; a second contact, connecting with the secondelectrode; and a third contact, connecting with the third electrode.

The second part of the aforesaid first electrode further has N secondfractures, N being a natural number greater than 0, each of the N secondfractures being located between two adjacent first resistance elementsor disconnecting at least one first resistance element from the firstelectrode, and the N second fractures divide the first part into (N+1)parts.

The aforesaid second electrode (2) further includes M third fractures, Mbeing a natural number greater than 0, each of the M third fracturesbeing located between two adjacent first resistance elements ordisconnecting at least one first resistance element from the secondelectrode, and the M third fractures divide the second electrode into(M+1) parts.

The aforesaid resistance structure may further include a thirdelectrode, a plurality of fifth electrodes, wherein one end of each ofthe fourth electrode is connected to the second electrode or the firstelectrode, and the other end thereof is connected to the thirdelectrode. At least one of the second electrode and the third electrodemay have a plurality of first fractures, the first fractures beinglocated between two adjacent first resistance elements or fourthelectrodes or disconnecting at least one first resistance element or thefourth electrode from the second electrode.

According to some embodiments, the information identification deviceincludes one of the above resistance structures, wherein at least partof the plurality of first resistance elements has a linear shape.

According to some other embodiments, the information identificationdevice includes one of the above resistance structures, wherein at leastpart of the plurality of first resistance elements has a curved shapesuch as a sawtooth shape.

According to some other embodiments, the biosensor includes one of theaforesaid information identification devices. The informationidentification device and the working electrode 92 and the counterelectrode 93 are located on the same surface of the insulating baseplate 91, and the information identification device is electricallyisolated from the working electrode 92 and the counter electrode 93 orconnected to one of the working electrode 92 and the counter electrode93. The information identification device and the working electrode 92and the counter electrode 93 are located on different surfaces of theinsulating base plate 91.

According to some embodiments, a resistance structure unit may beprovided. The resistance structure unit may include any one of theaforementioned resistance structures. The resistance structure unit maybe used in an information identification device or other devices.

According to some embodiments, an information identification unit may beprovided. The information identification unit may include any one of theaforementioned resistance structures. The information identificationunit may be used in an information identification device or otherdevices.

According to some embodiments, the information identification device isused to identify the identification information through the ratio of anelectrical parameter characterized by the resistance structure to asecond electrical parameter.

According to some embodiments, the second electrical parameters includeresistance, voltage, or current.

According to some embodiments, the second electrical parameters aredependent or independent of the resistance structure.

According to some embodiments, the second electrical parameters are froma test instrument.

It is easy to understand that a resistance structure or a resistancestructure unit herein is not limited to be used in biosensor, but usedin other appropriate systems. The information identification unit or theinformation identification device described herein are not limited to beused in biosensor, but used in other appropriate systems.

For the method for judging the information identification devicedescribed herein, the electrode may be made of a conductive materialsuch as carbon or silver, and may be made on an insulating substrate byscreen printing, plating, etc.

The method for making information identification device is described bytaking screen printing as an example. The method includes making of ascreen mesh with a preset electrode shape, then printing the conductivematerial on the insulating substrate using the screen mesh to form acorresponding electrode. The fracture can be pre-set in the screen meshor made by the laser cutting or mechanical perforating method after theformation of electrode system. By taking the information identificationdevice 1 located on the front side of the biosensor body 9 as anexample, first the test paper production is completed, and then the testpaper testing is carried out. By selecting appropriate technicalparameters of this batch and according to the position of factures, thefractures are made by the laser cutting or mechanical perforatingmethod, thus, the information identification devices of this batch oftest papers are produced.

The electrode of the information identification device is made ofconductive material. If these electrodes are directly exposed to theenvironment, substances in the environment will adhere to the electrode,which will change the actual electrical parameters of the electrode,resulting in inaccurate test data. Thus, in the present invention, theelectrodes of the information identification device are coated with aninsulating layer, which may be a material having poor electricalconductivity such as a self-adhesive, a plastic sheet, or a UV-curableink, etc.

The biosensor of the information identification device in the presentinvention can be used to determine alcohol, glucose, uric acid, lactate,cholesterol, bilirubin, hemoglobin, alanine aminotransferase from ananalyte sample such as whole blood, urine, saliva, etc.

The present invention has been described with reference to severaltypical embodiments, but it should be understood that all terminologiesused herein are illustrative and exemplary, rather than restrictive. Asthis invention can be executed in a variety of forms without departingfrom the spirit or nature of the invention, it should be understood thatthe embodiments described above are not limited to any of the foregoingdetails, but it should be construed broadly within the spirit and scopeof the invention as defined by the appended claims. Therefore, allvariations and modifications made based on the claims or theirequivalents shall fall into the scope of protection of the invention.

What we claim:
 1. A resistance structure comprises: a first electrode; asecond electrode; a plurality of first resistance elements, wherein oneend of each of the first resistance elements is connected to the firstelectrode, and the other end thereof is connected to the secondelectrode; a first fracture, the first fracture dividing the firstelectrode into a first part and a second part, wherein the firstfracture is located between two adjacent first resistance elements; orwherein the first fracture disconnecting at least one end of the firstresistance element from the first electrode.
 2. The resistance structureaccording to claim 1, wherein the second part of the first electrodefurther has N second fractures, N being a natural number greater than 0,each of the N second fractures being located between two adjacent firstresistance elements or disconnecting at least one first resistanceelement from the first electrode, the N second fractures divide thefirst part into (N+1) parts, the third electrode is connected with oneof the (N+1) parts.
 3. The resistance structure according to claim 1,wherein the resistances of the plurality of first resistance elementsare the same as each other.
 4. The resistance structure according toclaim 1, wherein the resistances of at least part of the plurality offirst resistance elements are different.
 5. The resistance structureaccording to claim 1, wherein the material of the first electrode andthe second electrode is different from that of the first resistanceelement.
 6. The resistance structure according to claim 1, wherein boththe resistance of the first electrode and the second electrode is lessthan that of each first resistance element.
 7. The resistance structureaccording to claim 1, wherein the second electrode further has M thirdfractures, M being a natural number greater than 0, each of the M thirdfractures being located between two adjacent first resistance elementsor disconnecting at least one first resistance element from the secondelectrode.
 8. The resistance structure according to claim 1, wherein thefirst electrode and the second electrode include silver, and theplurality of first resistance elements include graphite.
 9. Theresistance structure according to claim 1, wherein the materials of theplurality of first resistance elements are the same as each other. 10.The resistance structure according to claim 1, wherein the sizes of theplurality of first resistance elements are the same as each other. 11.The resistance structure according to claim 1, wherein the plurality offirst resistance elements comprise a plurality of resistor stripesdisposed in parallel to each other.
 12. The resistance structureaccording to claim 1, wherein the plurality of first resistance elementscomprise at least one resistor discs.
 13. The resistance structureaccording to claim 1, wherein the material of part of the plurality offirst resistance elements is different from that of other firstresistance elements.
 14. The resistance structure according to claim 1,wherein the size of part of the plurality of first resistance elementsis different from that of other first resistance elements.
 15. Theresistance structure according to claim 1, wherein a fracture is formedby laser cutting or mechanical perforating way.
 16. The resistancestructure according to claim 1, wherein further comprising a firstcontact connecting with the second part of the first electrode; a secondcontact connecting with the second electrode.
 17. The resistancestructure according to claim 1, wherein further comprising a thirdelectrode, wherein the third electrode is connected to the first part ofthe first electrode.
 18. A resistance structure comprises: a firstelectrode; a second electrode; a plurality of first resistance elements,wherein one end of each of the first resistance elements is connected tothe first electrode, and the other end thereof is connected to thesecond electrode; N factures, the N factures dividing the firstelectrode into N+1 parts, wherein each of the N fractures is locatedbetween two adjacent first resistance elements; or wherein each of the Nfractures disconnecting at least one end of the first resistance elementfrom the first electrode, wherein N is a natural number greater than 0.19. A resistance structure comprises: a first electrode; a secondelectrode; a plurality of first resistance elements, wherein one end ofeach of the first resistance elements is connected to the firstelectrode, and the other end thereof is connected to the secondelectrode; N factures, the N factures dividing the first electrode intoN+1 parts, wherein each of the N fractures is located between twoadjacent first resistance elements; or wherein each of the N fracturesdisconnecting at least one end of the first resistance element from thefirst electrode, wherein N is a natural number greater than 0; a thirdelectrode; a fourth electrode; a first sub-resistance structure,comprising at least one resistor, where the first sub-resistancestructure connects the third electrode to at least one of the (N+1)parts of the first electrode; a second sub-resistance structure,comprising at least one resistor, where the second sub-resistancestructure connects the fourth electrode to at least part of the secondelectrode; a first contact, connecting one of the (N+1) parts of thefirst electrode; a second contact, connecting one of the second contactand the fourth electrode; and a third contact, connecting with the thirdelectrode.
 20. A resistance structure comprises: a first electrode; asecond electrode; a plurality of first resistance elements, wherein oneend of each of the first resistance elements is connected to the firstelectrode, and the other end thereof is connected to the secondelectrode; N factures, the N factures dividing the first electrode intoN+1 parts, wherein each of the N fractures is located between twoadjacent first resistance elements; or wherein each of the N fracturesdisconnecting at least one end of the first resistance element from thefirst electrode, wherein N is a natural number greater than 0; a thirdelectrode; a fourth electrode; a first sub-resistance structure,comprising at least one resistor, where the first sub-resistancestructure connects the third electrode to at least part of the secondelectrode or one of the (N+1) parts; a second sub-resistance structure,comprising at least one resistor, where the second sub-resistancestructure connects the fourth electrode to the third electrode or atleast part of the second electrode or one of the (N+1) parts; a firstcontact, connected to or connected via a third sub-resistance structureto one of the (N+1) parts of the first electrode, the secondsub-resistance structure at least comprises a resistance element; asecond contact; and a third contact, wherein, each of the second contactand the third contact is connected to one of the second electrode, thethird electrode and the fourth electrode.